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Molecular and Cellular Biology, April 1999, p. 2505-2514, Vol. 19, No. 4
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Requirement of RBP9, a Drosophila Hu Homolog, for
Regulation of Cystocyte Differentiation and Oocyte Determination
during Oogenesis
Jeongsil
Kim-Ha,
Juri
Kim, and
Young-Joon
Kim*
Center for Molecular Medicine, Samsung
Biomedical Research Institute, Sungkyunkwan University College of
Medicine, Kangnam-ku, Seoul 135-230, Korea
Received 5 October 1998/Returned for modification 18 November
1998/Accepted 17 December 1998
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ABSTRACT |
The Drosophila RNA binding protein RBP9 and its
Drosophila and human homologs, ELAV and the Hu
family of proteins, respectively, are highly expressed in the
nuclei of neuronal cells. However, biochemical studies suggest that the
Hu proteins function in the regulation of mRNA stability, which occurs
in the cytoplasm. In this paper, we show that RBP9 is expressed not
only in the nuclei of neuronal cells but also in the cytoplasm of
cystocytes during oogenesis. Despite the predominant expression of RBP9
in nerve cells, mutational analysis revealed a female sterility
phenotype rather than neuronal defects for Rbp9 mutants.
The female sterility phenotype of the Rbp9 mutants
resulted from defects in oogenesis; the lack of Rbp9
activity caused the germarium region of the mutants to be filled with
undifferentiated cystocytes. RBP9 appears to stimulate cystocyte
differentiation by regulating the expression of
bag-of-marbles (bam) mRNA, which encodes a
developmental regulator of germ cells. RBP9 protein bound
specifically to bam mRNA in vitro, which is required
for cystocyte proliferation, and the number of cells that
expressed BAM protein was increased 5- to 10-fold in the germarium
regions of Rbp9 mutants. These results suggest that RBP9
protein binds to bam mRNA to down regulate BAM protein
expression, which is essential for the initiation of cystocyte differentiation into functional egg chambers. In hypomorphic
Rbp9 mutants, cystocytes differentiated into egg chambers;
however, oocyte determination and positioning were perturbed.
Therefore, the concentrated localization of RBP9 protein in the oocyte
of the early egg chambers may be required for proper oocyte
determination or positioning.
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INTRODUCTION |
RBP9 is a Drosophila RNA
binding protein that shares a high level of sequence similarity with
Drosophila ELAV (41) and human Hu proteins (HuC,
HuD, Hel-N1, and HuR) (26, 29, 48). Proteins in this family
are known to be expressed in the nuclei of neuronal cells right after
the completion of mitotic division. RBP9 is expressed predominantly in
the nuclei of cells of the central nervous system (CNS), after the CNS
metamorphosis that occurs during the pupal period (19). The
related human Hu proteins are also expressed primarily in neurons and
are localized preferentially in the nuclei (8). Hu proteins
are absent in neuroblasts but appear in subsequent early-lineage
neurons and maturing neuronal cells. Thus, it has been suggested that
proteins in this family are required for neuronal maturation.
A role for Rbp9 in neurogenesis is further suggested by the
fact that ELAV is expressed specifically in the nuclei of all neurons
(41), and loss-of-function alleles of elav are
embryonic lethal, causing abnormal CNS development (40).
Recently, elav was suggested to regulate neuron-specific
splicing of neuroglian pre-mRNA (24), which
is consistent with the presence of RNA binding motifs in the ELAV
protein and its nuclear localization pattern.
However, in vitro studies suggest mRNA stability rather than
pre-mRNA splicing as a functional target of the Hu proteins. For
example, Hu proteins were shown to bind to stretches of U residues (the AU-rich element), and this interaction increases the
stability of the bound reporter mRNAs in a cell culture system (5, 9, 21, 26, 28, 32, 37). Given that Hu protein is
localized mainly in the nucleus, the cytoplasmic function of mRNA stabilization appears to be accomplished by the shuttling of
nuclear Hu proteins to the cytoplasm (9). Because Hu
protein binding sequences are often found in mRNAs that encode cell
growth regulators, it has been suggested that the Hu proteins control cell proliferation by regulating the stability of mRNAs that encode cell proliferation and/or differentiation signal proteins (3, 4,
5, 15, 21, 26, 32). For example, the in vitro binding of Hel-N1
protein to the 3' untranslated region (UTR) of Id mRNA,
which encodes a transcriptional repressor abundant in undifferentiated
neuronal precursor cells, suggests the involvement of Hel-N1 in the
regulation of nerve cell development (21). Recently, we
found that RBP9 down regulates the expression of extramacrochaetae (emc), a Drosophila
homolog of Id, possibly through the interaction of RBP9
protein with emc mRNA (36). These results
indicate that the RBP9 family of proteins binds to mRNAs and
functions in the regulation of cell growth and differentiation.
In addition to the two putative functions of the Hu protein gene family
discussed above, the expression of certain Hu proteins in nonneuronal
tissues indicates the existence of additional physiological functions.
In vertebrates, four closely related Hu homologs are expressed in
a distinct developmental pattern. For example, in adult frogs, elrC and
elrD are expressed exclusively in nerve cells during specific
developmental stages, whereas elrA is expressed in all tissues
throughout development. In particular, elrB is expressed in testis and
ovaries, in addition to its stage-specific expression in the brain
(13). Therefore, each of the related Hu homologs appears to
participate in the regulation of distinct developmental processes.
In this paper, we present the results of experiments designed to
decipher the function(s) of RBP9. We show that RBP9 protein is
expressed in the cytoplasm of ovaries, as well as in the nuclei of
neuronal cells. Analysis of Rbp9 mutants revealed that
although mutant cystocytes divide continuously, their differentiation
is arrested. In addition, we show that RBP9 protein binds
specifically to the U-rich region of bag-of-marbles
(bam) RNA in vitro and that BAM protein expression is
expanded in Rbp9 mutant ovaries. The specific interaction
between RBP9 protein and bam mRNA in vitro suggests
that RBP9 regulates either the stability or the translational
competence of bam mRNA, which in turn affects cystocyte differentiation of ovaries.
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MATERIALS AND METHODS |
Determination of the P-element insertion site at the 23C
region.
The DNA sequences flanking the P elements at the 23C
region of mutant Drosophila P944, P1046,
l(2)K00632, l(2)K05431,
l(2)K05432, l(2)K07920,
l(2)K12901,
l(2)K16124, and
l(2)K08224 strains (49) were amplified by inverse PCR (7). Each amplified fragment from P-element insertion lines was cloned, labeled with
32P, and hybridized to dot-blotted DNA from the following
cosmid contigs: 166H10, 16A8, 82F12, 78F3, 193E7, 122A10, 25A6, and
132H9 (44). To determine the exact location of a P element
within the cosmid clones that gave a positive signal in the dot blot hybridization analysis, the cosmid DNA was digested, blotted on a
nitrocellulose membrane, and probed with a P-element flanking sequence.
The exact location of the P-element insertion site was confirmed by
directly sequencing the amplified P-element flanking sequences as
described by Rao (38).
P-element-mediated mutagenesis.
The
l(2)K12901 strain has one P element
that contains a mini-white gene
(P[w+]) at the 23C region. To
mobilize the P element of l(2)K12901, we crossed l(2)K12901/CyO flies
with w/w; TMS, Sb
P[ry+ 
2-3]/Dr flies
(39), which harbor a helper P element (2-3) on
the third chromosome, and isolated male progeny that had both P
elements. After the helper P element provided the necessary transposase
to mobilize P[w+] to new insertion sites, we
crossed four of these males with four w1118
homozygous females in each vial (total number of vials = 2,500) to
eliminate the P[ry+ 2-3] element. Progeny
with eye colors different from those of the parents were screened for
mobilized P elements. No more than one fly with changed eye color was
selected from each vial and crossed with w1118
virgin females to establish lines that carried P elements that had
moved to new insertion sites. We established 900 lines from this
screening, and the location of each P-element insertion site was
determined by PCR. A PIR primer (7) complementary to the inverted repeats of the P element was used with eight 20-nucleotide Rbp9-specific primers for the PCR. These eight
Rbp9-specific primers are referred to as 199, 2109, 3219, 5125, 6710, 8370, 9909, and 11325. The numbers indicate the nucleotide
position of the 5' end of each primer in the Rbp9
genomic sequence (GenBank accession no. S55886), and these
eight primers corresponded to nearly every 1- to 2-kb region throughout
the entire gene.
Genomic DNA was prepared from each of the 900 P-element-mobilized lines
in groups of 10, and 1/20 of the DNA was used as a substrate for PCR
amplification with the PIR primer and a mixture of the eight
Rbp9-specific primers. When a specific PCR product from a
portion of Rbp9 was identified, genomic DNA was
again prepared from each individual line, and another round of PCR was
performed. For the lines identified as having P elements inserted at
new locations within the Rbp9 gene, the genomic
locations of the P elements were determined by a series of PCRs with
PIR and individual Rbp9-specific primers. When necessary,
the PCR fragments were sequenced to determine the exact location of the
P element insertion according to the method described by Rao
(38). Because most of the P-element insertions obtained from
the first mutagenesis were concentrated in the promoter region of
Rbp9, with no P elements inserted within the coding region,
we performed a second round of mutagenesis (screening an additional
2,264 lines with mobilized P elements) using
Rbp9P[1374], a line from the first
mutagenesis that has a P element located near the coding region of
Rbp9. We isolated three insertions that were localized to
the coding region of the Rbp9 gene:
Rbp9P[2690],
Rbp9P[2775] and
Rbp9P[2398].
As P elements in the
Rbp9 coding region could potentially be
spliced out during the transcription process to produce some
intact
Rbp9 messages, we remobilized the P element from the
Rbp9P[2775] and
Rbp9P[2398] strains to isolate
chromosomes with deletions within
Rbp9 gene
produced by
imprecise excision of the P elements. We obtained
56 and 34 P-element-excised lines from the
Rbp9P[2775] and
Rbp9P[2398] strains, respectively.
Among these, complete reversion of the
Rbp9 mutant phenotype
occurred in only five and seven cases of
the excision lines generated
from the
Rbp9P[2775] and
Rbp9P[2398] strains, respectively.
For an as yet unknown reason, imprecise
excisions occurred more
frequently at the
Rbp9 locus than at most
other loci. We did
not analyze all of the excision lines in detail.
Rather we carefully
characterized one of the P-element excision
lines, the
Rbp9
1 allele, which was generated by
imprecise P-element excision from
Rbp9P[2775].
Genomic DNAs prepared from the wild-type
(
w1118),
Rbp9P[2775], and
Rbp91 alleles were digested with
HindIII and blotted on a nitrocellulose
membrane for
Southern hybridization. The blotted nitrocellulose
membrane was
hybridized either with a
32P-labeled probe prepared from
the genomic DNA fragment encompassing
the entire
Rbp9 locus (the region from 3.4 kb upstream of the
first
transcriptional initiation site to nucleotide position 11347)
or with
probes prepared from the small
HindIII-digested
genomic
DNA fragments corresponding to nucleotide positions
1854 to 3815,
3815 to 6250, and 6250 to 9823. From this analysis, we
found that
the
Rbp91 allele has a chromosomal
deletion approximately from nucleotides
3400 to 7132, which removed the
P3 promoter and a 0.45-kb segment
of the coding region that included
the translational initiation
codon.
For germ line transformation, the 17.1-kb
Rbp9
genomic fragment, which harbors the region from 5.4 kb upstream
of the first
transcriptional initiation site (P1) to 1.1 kb downstream
of the
poly(A) signal, was inserted into pCaSpeR to make pCaSpeR-Rbp9.
Immunoblot analysis.
Five adult flies or the dissected
ovaries and the carcass from an equivalent number of flies were
homogenized with a disposable microdouncer in 30 µl of protein
sample loading buffer in a microcentrifuge tube. The fly debris was
removed by centrifugation (15,000 × g, 5 min). Protein
extracts (~4 µg of protein) were subjected to sodium dodecyl
sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) and transferred
to a nitrocellulose membrane for Western analysis (42).
Immunostaining of ovaries.
Ovaries (10 to 20 pairs) from
healthy young flies were dissected in 1× phosphate-buffered saline
(PBS) and fixed for 20 min in 4% paraformaldehyde in 1× PBS. The
fixed ovaries were washed several times over a 2-h period with PBT
(0.1% Tween 20 in 1× PBS). Anti-RBP9 antibody (Ab) was raised against
the C-terminal half of the protein and affinity-purified as
described elsewhere (19). Abs were diluted (RBP9 Ab, 1:50;
cytoplasmic BAM Ab [30], 1:200; and HTS [hu-li tai
shao protein] Ab [51], 1:5) in TNBTT (50 mM
Tris-HCl [pH 7.5], 150 mM NaCl, 0.1% bovine serum albumin, 0.1%
Triton X-100, 0.05% Thimerosal [Sigma, St. Louis, Mo.]), and the
ovaries were incubated in an Ab-containing solution at 4°C overnight.
After being washed once with TNBTT, ovaries were incubated with TNBTT
containing 2% goat serum for 30 min, washed with TNBTT for 2 h,
and then incubated with fluorescein isothiocyanate-conjugated secondary
immunoglobulin G (Sigma) in TNBTT at a 1:100 dilution for 2 h.
After washing with PBS, ovaries were mounted with Vectashield (Vector
Laboratories, Burlingame, Calif.) mounting medium. The RBP9 Ab was used
after incubation with ELAV-agarose (0.1 ml) for 4 h at 4°C to
remove any ELAV-cross-reacting material.
UV cross-linking assay.
Protein-DNA UV cross-linking assays
were performed as described elsewhere (20). Recombinant RBP9
(rRBP9; 60 ng) (36) was preincubated for 10 min with 10 µg
of yeast tRNA in a 10-µl reaction mixture that contained 1 µl of
10× reaction buffer A (32 mM MgCl2, 20 mM ATP, 1 mg of
bovine serum albumin per ml, 60 mM HEPES-KOH [pH 7.9]). The 3' UTR of
bam mRNA (450 bp between the termination codon and the
polyadenylation signal) was prepared by PCR amplification of wild-type
Drosophila cDNA with primers bam5 (5'-TTT CTA GAA CTA ATG
CTG TGC ACA TCG AT-3') and bam3 (5'-TTT CTA GAT GAC TTT CAA AAT ACA AAT
G-3'). The amplified fragment, which was digested with XbaI,
was cloned into the XbaI site of pBluescript KS+II (Stratagene) to make pKSBam3UTR, and the insert was sequenced to
confirm the absence of a mutation. An RNA probe encoding the bam 3' UTR (containing three putative RBP9 binding sites
[RBP9BS] at 274, 371, and 388 bp from the termination codon) was
transcribed by T7 RNA polymerase in the presence of
[32P]UTP from the pKSBam3UTR template that has been
linearized with BamHI. The 32P-labeled RNA probe
(100 fmol) was added to the reaction mixture, and the sample was
incubated for an additional 10 min at room temperature. The sample was
placed on ice and irradiated with UV light (105
ergs/mm2) with use of a Stratagene (La Jolla, Calif.) UV
cross-linker. The RNA was digested with RNase A (30 µg) for 15 min at
37°C and mixed with protein gel loading buffer. Samples were
boiled for 90 s and subjected to SDS-PAGE and autoradiography. For
UV cross-linking competition assays, a 20- to 400-fold excess of
competitor RNA oligonucleotides was added to the reaction mixtures
together with the 32P-labeled RNA probes. The competitor
RNA oligonucleotide RBP9BS (sense strand) was designed on the basis of
the consensus binding sequences of rRBP9 (UUUXUUUU) (36) and
Hel-N1 (RWUUUAUUUWR) (10), which were
identified with the use of SELEX (25). The RNA
oligonucleotides used for these assay were RBP9BS sense (5' UUG AUU UAU
UUU GAU UUU AUU UAG UU 3') and RBP9BS antisense (5' GAA AAA AAA AGA AAA
AAA AAA GAA 3').
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RESULTS |
Expression of RBP9 in the cytoplasm of early developing cystocytes
during oogenesis.
To examine whether the Drosophila Hu
homolog RBP9 is expressed in germ line cells, we dissected ovaries
from wild-type flies and examined the expression of RBP9 in both
the ovaries and the carcass. Western analysis showed that RBP9
was expressed in ovaries as well as in the carcass where the CNS is
retained (Fig. 1A).
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FIG. 1.
Expression and localization of RBP9 in the ovaries. (A)
Expression of RBP9 protein in ovaries. Ovaries were dissected from
wild-type flies, and whole-cell extracts were prepared from the
dissected ovaries (O) and carcass (C). The whole-cell extracts were
resolved in an SDS-polyacrylamide (10%) gel and immunoblotted with
affinity-purified anti-RBP9 antibody. As a protein loading control,
the same blot was probed with an antibody to yeast TATA binding
protein (TBP); the cross-reacting protein bands are shown. (B)
Cytoplasmic localization of RBP9 protein in wild-type ovaries.
Ovaries were stained with anti-RBP9 antibodies and analyzed by
confocal microscopy. The ovariole in the middle shows, from left
to right, the germarium regions (1, 2a, 2b, and 3) and stage 2 egg
chamber (S2). The oocytes at the posterior of each egg chamber are
marked with arrows. In the stage 3 egg chamber (S3), RBP9 staining is
detected only in the oocyte.
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We next sought to determine the developmental time and location of RBP9
expression in wild-type fly ovaries by staining them
with anti-RBP9 Ab.
RBP9 was first detected in the cytoplasm of
the 16 cystocytes of
germarium region 2a, which had just completed
four mitotic divisions
(
30) (Fig.
1B). As the 16-cell cluster
of cystocytes
moved to germarium region 3, where follicle cells
completely surround
the cystocytes to form an egg chamber, RBP9
was still present in all 16 cells (Fig.
1B). The concentration
of RBP9 began to diminish as egg
chambers left the germarium and
developed into stage 2 egg chambers
(stages are as described in
reference
22). However,
the highest concentration of RBP9 still
remained in the cytoplasm of
the most posterior cell, which will
become an oocyte. In stage 3 egg
chambers, RBP9 was nearly gone
from the cystocyte and present in
only small amounts in the oocyte.
The cytoplasmic localization of RBP9
is intriguing, because no
other Hu family protein has been shown to
be expressed predominantly
in the cytoplasm in normal
tissue.
Isolation of Rbp9 mutant alleles by P-element-induced
mutagenesis.
The distinct localization pattern of RBP9 in the
cytoplasm of ovaries, in addition to the nuclei of cells of the CNS,
provided a unique opportunity to examine both the cytoplasmic and
nuclear functions of Rbp9 during development. These
observations prompted us to isolate a collection of Rbp9
mutants. Because our initial attempt to isolate Rbp9 mutants
by using ethyl methanesulfonate treatment was not successful
(18), we used a local P-element mutagenesis protocol
(see Materials and Methods). As a first step, we screened existing fly
strains that had P elements inserted at the 23C region for one that
contained a P element close to the Rbp9 locus. Southern blot
analyses performed on Rbp9 genomic clones with the
P-element flanking sequences as probes revealed that the
l(2)K12901 strain contains a P
element inserted within the Rbp9 gene. Sequence analysis of
the P-element flanking regions confirmed its location at the
Rbp9 intron upstream of the third promoter (Fig.
2).
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FIG. 2.
Locations of P-element insertions in Rbp9
mutant alleles isolated by P-element-induced mutagenesis. P1, P2, and
P3 indicate the three alternative Rbp9 promoters; the
splicing patterns of alternatively used exons are shown with lines. The
P-element insertion sites of
I(2)K12901 and
Rbp9P[1374] flies used to initiate
P-element local mutagenesis, the ultimate locations of the P elements
in the 87 lines isolated, the four Rbp9 mutant alleles
(P[2567], P[2398],
P[2690], and P[2775])
described in this paper are indicated, and the locations of primers
used to map the insertion sites of P elements are indicated. The number
above each arrow at the top indicates the 5' end of the primer
corresponding to the nucleotide number of Rbp9 as described
by Kim and Baker (19).
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Although the
l(
2)
K12901 strain was
originally isolated as a P-element-induced lethal line, homozygotes
were later shown to
be weak but viable, with wings that remained
folded after eclosion.
However, the mutation that caused
the folded wing phenotype segregated
away from the P-element
insertion when
l(
2)
K12901 strain
was back-crossed
to wild-type flies. Immunoblot analysis with
anti-RBP9 antibody
showed that
l(
2)
K12901 strain expressed
wild-type levels of RBP9
protein (Fig.
3A). Therefore, the P-element
insertion at the
Rbp9 intron had no effect on
Rbp9 expression.
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FIG. 3.
Immunoblot analysis of Rbp9 alleles. (A)
Crude fly extracts (4 µg) were analyzed by Western blotting with
anti-RBP9 Ab. The fly strains analyzed are indicated above the lanes
(w1118 [w] was used as wild type). (B) The
expression of RBP9 protein in ovaries (O) and carcass (C) is shown
for wild-type and Rbp9P[2567]
female flies. As a loading control, the same blot was probed with an Ab
to yeast TATA binding protein (TBP); the cross-reacting protein
band in each lane is shown.
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To generate an RBP9 protein null mutant, we mobilized the P element
of
l(
2)
K12901 strain to locations
within the
Rbp9 coding
region. We screened a total of
4.5 × 10
5 flies and isolated 3,164 lines with
mobilized P elements. From
these, we isolated 87 lines with P elements
within the
Rbp9 gene.
Most of the P-element insertions
occurred at several insertion
hot spots near the promoters and 5'
UTR. In only three cases did
P elements translocate to the
Rbp9 coding sequences; we refer
to these strains as
Rbp9P[2690],
Rbp9P[2775], and
Rbp9P[2398] (Fig.
2).
Despite the extensive mutagenesis of the
Rbp9 gene,
all homozygotes of the P-element insertion lines described above
were
viable, and the level of RBP9 expression was not affected by the
P-element insertions in most cases. However, no detectable amount
of
RBP9 protein was observed from the three
Rbp9 alleles
harboring
P elements in the
Rbp9 coding region
(
Rbp9P[2690],
Rbp9P[2775], and
Rbp9P[2398]) (Fig.
3A).
Because RBP9 protein is expressed in ovaries as well as in the CNS,
we examined the remaining P-element lines for mutants
that were
defective in RBP9 expression in only one of these tissues.
Although
immunoblot analysis of whole-fly extract from
Rbp9P[2567] detected RBP9 levels
comparable to those of wild-type flies (data
not shown), when we
tested ovary and carcass separately, we detected
RBP9 only in the CNS,
which was represented by the carcass extract,
not in the ovaries (Fig.
3B).
To determine the exact locations of the P elements in these
Rbp9 alleles, we sequenced each P-element flanking region.
Strain
Rbp9P[1374], which was used
to start the second round of P-element mutagenesis
(see Materials
and Methods), had a P element inserted at nucleotide
position 4668 of exon 4. In addition to this P element, strains
Rbp9P[2690] and
Rbp9P[2398] each contained a P
element at nucleotide positions 7197 and 6937,
respectively. In
contrast,
Rbp9P[2775] contained a
single P element inserted at nucleotide position
7132, without the
original P element at position 4668 (Fig.
2).
All of these P elements
disrupted the
Rbp9 coding region within
the first RNA
binding
domain.
Female-specific sterility of Rbp9 mutants.
Although the predominant expression of RBP9 in the adult CNS suggested
a putative function of RBP9 in CNS development, we could detect no
obvious defect in mutant viability, CNS development, or behavior.
However, each Rbp9 mutant showed some degree of defects in
fertility. Rbp9P[2690] homozygotes
were completely sterile, while
Rbp9P[2775] and
Rbp9P[2398] homozygotes showed a
reduction in fertility. The numbers of progeny eclosed from
Rbp9P[2690],
Rbp9P[2775], and
Rbp9P[2398] homozygous parents were
0, 3, and 23%, respectively, of those eclosed from wild-type parents
(Table 1). When homozygous females of
each of the Rbp9 mutant alleles were crossed to wild-type
males, the degree of sterility observed was similar to that of
each homozygote. On the contrary, none of the mutant males
showed a defect in fertility when crossed to wild-type females
(Table 1). Therefore, Rbp9 is required for fertility only in
females.
In addition, it appears that RBP9 expression in the ovaries but
not in the CNS is required for fertility. The
Rbp9P[2567] homozygote showed
normal RBP9 expression in the CNS but not in
the ovaries. The number of
progeny eclosed from
Rbp9P[2567] homozygote parents was
only 28% of those eclosed from wild-type
parents (Table
1). This
result suggests that (i) the oogenesis
defect observed in strains
bearing the
Rbp9P[2567] allele was
caused solely by the loss of
Rbp9 expression in ovaries
and (ii) expression of
Rbp9 is regulated in a
tissue-specific
manner.
Although all four of the
Rbp9 mutants studied apparently
expressed no RBP9 protein in the ovaries, they exhibited various
degrees of sterility. To test whether the incomplete penetrance
of the sterility phenotype in strains carrying certain
Rbp9 mutant
alleles resulted from residual
Rbp9
activity, we placed the
Rbp9 mutant alleles over the
deficiency chromosome, which removes most
of the 23C region including
Rbp9. These hemizygote flies showed
sterility with 100%
penetrance. Therefore, certain of the above-cited
Rbp9
mutants appear to possess a partially active
Rbp9 gene.
Because residual
Rbp9 activity may result from the synthesis
of a low amount of intact mRNA by the splicing out of the inserted
P element, we remobilized the P element to induce its imprecise
excision. This generated a strain with a chromosomal deletion
that
included the translational initiation site and the first
N-terminal 150 amino acids (
Rbp91; see Materials and
Methods). Homozygotes of the
Rbp91 allele
showed a complete female sterility phenotype (data not
shown).
Therefore, a small amount of
Rbp9 activity must be
retained
in the
Rbp9P[2775],
Rbp9P[2567], and
Rbp9P[2398] strains, whereas the
Rbp9P[2690] allele is very close to
null. The sterility phenotype of all
the
Rbp9 alleles was
rescued completely by germ line transformation
of a DNA fragment
that encompassed the
Rbp9 gene (Table
1). Therefore,
the female sterility phenotype is a genuine
Rbp9 null
phenotype.
Defective ovary development in Rbp9 mutants.
To
understand how the loss of Rbp9 activity caused female
sterility, we examined the phenotypes of ovaries isolated from
Rbp9 mutant strains. In whole ovaries examined by nuclear
(4',6-diamidino-2-phenylindole [DAPI]) staining (Fig.
4), ovarioles from strains bearing
the Rbp9 alleles that showed the most severe sterility
phenotype (Rbp9P[2690] and
Rbp91) were filled with egg chambers
containing abnormal number of cystocytes that never developed beyond a
stage 6 egg chamber (Fig. 4A and B and data not shown). In addition,
the germarium regions were enlarged as often detected in ovarian tumors
(11, 23, 31, 35, 43). In a few cases the ovarioles were
completely devoid of egg chambers. As the Rbp9 mutant flies
aged, we observed that the underdeveloped egg chambers became filled
with numerous small cells (the "tumorous bag" phenotype).
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FIG. 4.
Allele-specific phenotypes of Rbp9 mutant
ovaries. The anterior end of the ovaries is oriented at the right side
of each panel except panel F, where the anterior end is oriented toward
the top. Ovaries consist of ovarioles in which progressively more
advanced stages of oogenesis are arranged linearly from anterior (right
or top in panel F) to posterior (left or bottom in panel F). (A to F)
DAPI staining patterns of ovaries from wild-type and mutant flies. (A)
Wild-type ovaries. Each egg chamber consists of one oocyte and 15 nurse
cells surrounded by follicle cells. (B to E) Ovaries from
Rbp9P[2690],
Rbp9P[2775],
Rbp9P[2398], and
Rbp9P[2567] homozygous flies,
respectively. (F) Ovaries from an
Rbp9P[2398]/Df
hemizygous fly. Egg chambers with fewer or more than 15 nurse cells are
indicated with short or long arrows, respectively. Black arrowheads
represent egg chambers with tumorous cells.
|
|
The defects in oogenesis in the
Rbp9P[2775] mutant were slightly
less severe than those in the
Rbp9P[2690] ovaries. Most of the
defects observed in
Rbp9P[2690]
flies were present in
Rbp9P[2775]
flies; however, a few egg chambers in
Rbp9P[2775] flies did
progress to later developmental stages, producing mature
egg
chambers (Fig.
4C). The other two
Rbp9 mutants
(
Rbp9P[2398] and
Rbp9P[2567]) with less severe
sterility had only minor defects in oogenesis
(Fig.
4D and E). The
overall structure of the ovaries was similar
to that of wild-type
flies, but egg chambers with abnormal numbers
of nurse cells were often
detected.
Although the various
Rbp9 mutant homozygotes
showed distinct oogenesis defects, all of the hemizygous flies
that carried one
of the
Rbp9 mutations over a deficiency
chromosome showed the
most severe oogenesis defects. Most ovarioles
from these flies
were filled with several tumorous bags that contained
hundreds
of cells instead of 15 polyploid nurse cells and one oocyte
(Fig.
4F). The severity of the defects in oogenesis in different
alleles
correlated with the degree of the sterility observed in those
alleles.
Requirement of Rbp9 for oocyte determination and
positioning.
In addition to the function of Rbp9
in the regulation of germ cell proliferation and differentiation,
the specific localization of RBP9 protein in the oocyte of the
early egg chambers suggests that RBP9 is also required for proper
oocyte determination. Because the strong Rbp9 mutant alleles
(Rbp9P[2690] and
Rbp91 alleles) did not produce egg chambers
developed sufficiently to allow study of the later stage-specific
function of Rbp9, we examined the oocyte determination
process of hypomorphic Rbp9 (Rbp9P[2398] and
Rbp9P[2567]) mutants, which contain
normally shaped egg chambers. In wild-type ovaries, oskar
(osk) mRNA is concentrated in the oocytes located at the
posterior end of each egg chambers (Fig.
5A). However, in the
Rbp9P[2398] mutant ovaries,
osk mRNA often accumulated in more than one cell (Fig.
5B). Even when osk mRNA did accumulate in only one cell, it often was not positioned at the most posterior end of the egg chambers. This alteration in the distribution pattern of osk
mRNA demonstrated that Rbp9 function is also required
for proper oocyte determination and positioning.
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FIG. 5.
Pattern of osk mRNA distribution in
wild-type (A) and Rbp9P[2398] (B)
ovaries. The hybridization signal appears as darkly staining material.
Arrowheads indicate egg chambers that either contain an osk
mRNA-accumulating cell that is not located at the posterior of egg
chamber or have more than one cell that accumulates osk
mRNA. Progressively older egg chambers are shown from left to
right.
|
|
Requirement of Rbp9 function for regulation of
cystocyte differentiation.
Immunostaining of wild-type ovaries
with antibodies to HTS (51), a fusome component, initially
shows two stem cells with dot-shaped spectrosomes; as the
cystocytes divide, fusomes with branched structures are observed.
The branched fusome structure is observed most clearly when
cystocytes lose the rosette conformation after the fourth round of
mitotic division and take on a lens-shaped appearance in the most
anterior section of germarium region 2 (Fig.
6A). This cyst development requires a
number of genes, including ovarian tumors (otu),
benign gonial cell neoplasm (bgcn), and bam (11, 12, 46). Analysis of the germarium
regions of bgcn or bam mutants with
antibodies to fusome components reveals that most of the cystocytes
have dot-shaped or single-branched fusomes, whereas the cystocytes of
otu mutant ovaries have branched fusomes despite the
similar tumorous phenotype (27, 31, 47).
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FIG. 6.
Immunostaining of the germarium with Abs to HTS (A and
B) or BAM (C to E). Wild-type (A and C) and
Rbp91 mutant (B, D, and E) ovaries were
stained with Abs to the cytoplasmic BAM and HTS proteins. The
anterior ends of the germarium are at the left of each panel. (A) At
the tip of the germarium, a fusome in the stem cell appears as a
spherical dot (arrowhead). As cystocytes divided, the fusome becomes
elongated and finally appears as a branched structure (long arrow). (B)
Most of fusomes in the Rbp9 mutant appear to be branched
(short arrow) but do not have the shape of a fully branched structure.
Some cystocytes contain fusomes in the shape of spherical dots without
an obvious visible connection between each other (*). (C) Cytoplasmic
staining of BAM protein is clearly visible in a cluster of four
cystocytes located near the anterior end of the wild-type germarium.
(D) Rbp9 mutant germarium contains an increased number of
cells that express BAM proteins. Several clusters of cystocytes are
stained with BAM Ab. (E) BAM protein is still detectable even when
the cystocytes show a lens-shaped morphology, which is usually detected
in germarium region 2b (arrow).
|
|
We stained
Rbp9 mutant ovaries against anti-HTS to see
whether these mutants exhibit a dot-shaped or branched fusome
structure.
Most of the fusomes in the
Rbp9 mutant germarium
were branched;
however, fully branched fusome structures were faintly
detectable
(Fig.
6B). The rest of the fusomes in the mutant appeared as
spheres,
but the shape of the fusome differed from that of the
spectrosome
of wild-type flies. Instead of well-separated, single
dot-shaped
fusomes, several sphere-shaped fusomes were located very
close
to each other without detectable connections (Fig.
6B). Some of
the sphere-shaped fusomes were connected with thin linear fusomes.
These results show that cystocytes in the
Rbp9 mutant
germarium
were not able to differentiate into 16-cell clusters that can
be enveloped by somatic follicle cells. Therefore,
Rbp9 is
required
for the initiation of cystocyte
differentiation.
BAM proteins are known to be expressed in mitotically active
cystocytes in germarium region 1 and are not normally expressed
in
the germ cells of germarium region 2 (
30). Therefore, we
stained
Rbp91 mutant ovaries with anti-BAM Ab
to determine the developmental
location of BAM protein expression.
In wild-type ovaries, only
one or two cystocytes expressing BAM
protein were detected in
each germarium (Fig.
6C). On the other
hand, in
Rbp91 mutant ovaries, the tumorous
germarium region was composed of
several clusters of cystocytes that
were expressing BAM protein
(Fig.
6D). Occasionally,
cystocytes developed to a lens-shaped
morphology, which is
characteristic of germarium region 2b cystocytes,
and BAM protein
was still expressed in those cystocytes (Fig.
6E). This prolonged
expression of BAM protein is never detected
in wild-type
cystocytes. The expression of BAM protein in multiple
cystocytes of
the
Rbp9 mutant germarium suggests that the mutant
cystocytes are arrested early in development, at a stage prior
to
their differentiation into an egg
chamber.
Binding of RBP9 to the 3' UTR of bam mRNA in
vitro.
Our observation that an increased number of Rbp9
mutant cystocytes express BAM protein suggests that Rbp9
may be required for the down regulation of BAM expression. For example,
RBP9 may bind to bam mRNA and regulate its stability or
translatability. In vitro binding assays identified the sequence
UUUAUUU as an RBP9 consensus binding site. Examination of
the nucleotide sequence of bam mRNA by using the
WINDOW program (Wisconsin Package; GCG Inc.) identified
three UUUAUUU sequences within the 3' UTR, located 177, 80, and 63 bp upstream of the poly(A) signal. To test whether these
repeats represent authentic RBP9BS, we used a UV
cross-linking assay to detect RBP9 binding to the bam
mRNA 3' UTR. As shown in Fig.
7B, the 3' UTR of bam
mRNA cross-linked efficiently to RBP9 protein (lane 2).
To confirm the specificity of binding, we tested the ability of sense
and antisense RNAs to compete for RBP9 binding. When added to the
binding reaction, sense competitor RNA oligonucleotide that contained
two repeats of the RBP9BS efficiently competed with the bam
3' UTR probe for RBP9 binding (lanes 3 to 5). Conversely, antisense RNA
that contained the complementary RBP9BS sequences did not compete
efficiently for RBP9 binding, even when a 400-fold excess was added to
the binding reaction (lanes 6 to 8). These results indicate that RBP9
binds specifically to the bam mRNA 3' UTR and suggest
that RBP9 may down regulate BAM expression by interacting with the
AU-rich elements of bam mRNA.
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|
FIG. 7.
Binding of RBP9 protein to the U-rich elements
within the 3' UTR of bam mRNA. (A) locations of the
UUUAUUU motifs () in the 3' UTR of bam
mRNA. The second and third Rbp9 binding motifs () are located
9 bp apart near the poly(A) signal. The probe used for the UV
cross-linking assay is shown. The locations of the bam
coding region and poly(A) tail (AAAAA) are marked. (B) UV cross-linking
of RBP9 protein to bam mRNA. Recombinant RBP9
protein (60 ng) was UV cross-linked to the 3' UTR of bam
mRNA. RBP9BS sense (lanes 3 to 5) and antisense (lanes 6 to 8) RNA
oligonucleotides were added as competitor RNAs to the binding reaction
in 40-, 120-, and 400-fold excesses, respectively.
|
|
| |
DISCUSSION |
Because the RNA binding proteins RBP9, ELAV, and Hu were
identified originally in nerve cell nuclei, researchers suggested that
they function in neurospecific pre-mRNA processing (19, 29,
48). However, the results of subsequent studies on Hu proteins suggested that they play a role in the regulation of mRNA stability in the cytoplasm of developing neuronal cells
(5, 9, 21, 26, 28, 32, 37). Although Hu proteins were shown recently in a tissue culture system to increase the stability of
reporter mRNAs that contain Hu protein binding sequences
(9), direct evidence of such a cytoplasmic function obtained
under physiological conditions was lacking. In this study, we show that RBP9 is localized in the cytoplasm and regulates BAM expression in
differentiating germ cells. These findings strongly support the
idea that the RBP9 family proteins regulate mRNA stability and/or translational competence of mRNAs that encode cellular differentiation signal proteins.
In addition to the proposed cytoplasmic function of Rbp9,
the detection of Rbp9 in a tissue outside the CNS is
intriguing. Although elrA, elrB, and HuR were found in cells other than
neurons, their physiological roles in these nonneuronal cells have not been established (13, 29). In this study, genetic,
molecular, and morphological examination of Rbp9
mutants revealed a requirement for Rbp9 in the regulation of
female germ cell differentiation. The absence of RBP9 protein
in the germarium caused cystocytes to be arrested at various
undifferentiated stages, and tumorous ovarioles filled with the
accumulating cystocytes were formed. This defect seems to be mediated
through bam, as RBP9 interacts with bam mRNA
in vitro and BAM expression is expanded in the Rbp9 mutants.
Moreover, the unusual expression of BAM in germarium region 2b
cystocytes suggests that the expansion of BAM expression is not just a
simple reflection of the increase of early stage cystocytes in the
tumorous ovarioles. Rather, we suggest that down regulation of BAM
expression is required for proper cystocyte differentiation and that
this process is not properly regulated in the Rbp9 mutants.
It has been suggested that bam serves multiple functions in
a number of the developmental stages of oogenesis. A loss of function mutation in bam causes female cysts to proliferate like stem
cells (30, 31), whereas ectopic expression of bam
in ovaries, including the stem cells, eliminates oogenic germ line stem
cells (33). Therefore, bam appears to function in
suppressing stem cell fate in stem cell daughters and to promote
cystoblast differentiation (33). Analysis of
encore mutants suggested additional functions for
bam during the later stages of cystocyte development. BAM is
expressed only in the dividing cystoblast and cystocytes and is removed
from the cystocytes after four rounds of mitotic division (30). As the expansion of bam transcripts is
correlated with one extra round of mitosis in the encore
mutant germarium, bam may act as part of a titratable
counting mechanism whose levels determine the number of mitotic
divisions (14). Although both Rbp9 and
encore are involved in the regulation of cystocyte
proliferation and differentiation through their interactions with
bam, they have quite different mutant phenotypes (reference
14 and this study) and, thus, appear to act by
distinct mechanisms. Because RBP9 binds to the 3' UTR of bam
transcripts in vitro, RBP9 may be involved in the destabilization of
residual bam transcripts or in the process of making
bam transcripts unsuitable for translation. This is
consistent with our recent finding that the level of emc mRNA, which also interacts with RBP9 in vitro, is down regulated by
Rbp9 in vivo (36).
The observations that RBP9 protein is concentrated in the oocyte of
wild-type early-stage egg chambers and that mispositioned or abnormal
numbers of oocytes were detected in hypomorphic Rbp9 mutants
suggest that Rbp9 is required not only for cystocyte
differentiation but also for oocyte development. This process could be
mediated through a target RNA(s) other than the bam
transcript. Because RBP9 binds to a rather simple RBP9 consensus
binding sequence in vitro and this sequence is found in many
transcripts, a number of RNAs expressed in the ovary have the potential
to interact with RBP9 (36). However, the observation
that all transcripts that contain the RBP9 consensus binding sequences
are not regulated by RBP9 (36) suggests that additional
cis- or trans-acting components must be required
for the functional interaction of RBP9 with its specific target RNAs in
vivo. Therefore, the identification of these additional factors is
necessary to elucidate the mechanism by which RBP9 regulate its target RNAs.
Rbp9 appears to function in at least one more process during
oogenesis. Although we did not observe gross egg chamber defects by
DAPI staining in weak Rbp9 alleles
(Rbp9P[2398] and
Rbp9P[2567]), the fertility of
these alleles measured by the number of eclosed adult flies remained
low. This reduction in fertility can be explained in two ways. First,
the overall number of eggs laid by the mutants was smaller than that
laid by wild-type flies (data not shown). Second, eggs laid by the weak
Rbp9 mutant flies were somewhat defective in axis formation.
About 20% of the mutant embryos showed body patterning defects when
determined by cuticle preparation. Posterior body patterning defects
(45) were most often detected, while some embryos showed a
dorsalized phenotype (data not shown). Therefore, Rbp9
appears to be required for multiple distinct developmental steps during oogenesis.
Although we detected several oogenesis defects in Rbp9
mutant flies, we observed no defect in CNS function. Serial sections of
adult flies carrying either an Rbp9 null allele or wild-type Rbp9 were stained with DAPI, anti-RBP9 Ab, and monoclonal Ab
(MAb) 22C10 (52) in order to visualize nuclei, RBP9, and
neural cytoplasmic antigen, respectively. The nuclear staining patterns
showed no morphological differences between wild-type and mutant flies, despite the lack of RBP9 protein in the mutant CNS (data not
shown). Neurons from Rbp9 mutant strains expressed
neuron-specific antigen, and axons stained normally with MAb 22C10. The
absence of an effect on the nervous systems of Rbp9 mutant
flies was extended further in that no obvious abnormalities were
detected in flight, feeding, or mating behaviors (data not shown). The
coexpression of ELAV and RBP9 in the adult CNS may provide functional redundancy.
Because perturbation of germ line sex determination has been reported
with mutations that give rise to the tumorous ovarian phenotype
(34), we examined the sex-specific pattern of Sex lethal (Sxl) pre-mRNA splicing in Rbp9
mutants with respect to the presence of the male-specific
Sxl exon. The male-specific Sxl transcript was
not observed in wild-type or
Rbp9P[2567] females (data not
shown). However, Rbp9P[2775]
females had a small amount and
Rbp9P[2690] homozygous females had
a higher concentration of the male-specific Sxl transcript
(data not shown). The observation that greater amounts of the
male-specific Sxl transcript are produced in mutants with a
more severe ovarian tumor phenotype implies that germ line sex
determination is correlated with the cystocyte differentiation process
of the germarium. Because the initial steps of the cystocyte differentiation process are very similar for oogenesis and
spermatogenesis, the arrest of cystocyte development prior to the
differentiation of egg chambers may send an erroneous signal to the
cystocyte in the germarium causing the cells to follow a male-like
developmental pathway.
Although Rbp9 is expressed mainly in postmitotic cells both
in the CNS and in the ovaries, the distinct cellular localization patterns of RBP9 protein in each tissue type suggests a unique function for RBP9 in each location. SXL is another example of an RNA
binding protein with distinct tissue-specific functions. SXL was
originally identified as an alternative-splicing regulator in the
somatic sex determination pathway (1, 6). Despite the
presence of a considerable amount of cytoplasmic SXL protein in
certain tissues, only the nuclear protein was considered to be
functional. However, it was later shown that cytoplasmic SXL protein binds to the UTR of msl-2 mRNA and inhibits
its translation (2, 17). Although SXL executes two
different functions in two distinct cellular locations, both
processes are mediated by the recognition of similar
polypyrimidine elements that are found in the UTRs of
msl-2 and the introns of genes involved in sex determination. The localization of RBP9 and SXL proteins in two distinct cellular compartments could be guided by their
association with tissue-specific localization factors or by
modification of their phosphorylation status. An understanding of the
cellular processes that regulate protein localization should aid us
in deciphering the mechanisms used by RBP9 and SXL in their various modes of developmental regulation.
| |
ACKNOWLEDGMENTS |
We thank J. Hall for the analysis of Rbp9 mutant
behavior, I. Siden-Kiamos for cosmids, and the Berkeley
Drosophila Genome Project for P-element lines. We also thank
C. Kim for MAb 22C10. We offer special thanks to D. McKearin for BAM
and HTS antibodies.
This work was supported by grants from SBRI (B-96-004) and Korea
Science and Engineering Foundation, Republic of Korea
(98-0403-04-01-5), to Y.-J.K. and J.K.-H.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Center for
Molecular Medicine, Samsung Biomedical Research Institute,
Sungkyunkwan University College of Medicine, 50 Ilwon-dong,
Kangnam-ku, Seoul 135-230, Korea. Phone: 82-2-3410-3638. Fax:
82-2-3410-3649. E-mail: yjkim{at}smc.samsung.co.kr.
| |
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Molecular and Cellular Biology, April 1999, p. 2505-2514, Vol. 19, No. 4
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Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
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